Method and apparatus for optical sensing

ABSTRACT

Apparatus and methods for fast quantitative measurement of perturbation of optical fields transmitted, reflected and/or scattered along a length of an optical fibre can be used for point sensors as well as distributed sensors or the combination of both. In particular, this technique can be applied to distributed sensors while extending dramatically the speed and sensitivity to allow the detection of acoustic perturbations anywhere along a length of an optical fibre while achieving fine spatial resolution. Advantages of this technique include a broad range of acoustic sensing and imaging applications. Typical uses are for monitoring oil and gas wells such as for distributed flow metering and/or imaging, seismic imaging, monitoring long cables and pipelines, imaging within large vessel as well as for security applications.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation application and claims benefit under 35 U.S.C. §120 to U.S. patent application Ser. No. 13/322,449, filed Nov. 23, 2011, which is a National Stage application of International Application No. PCT/GB10/50889, filed May 27, 2010. PCT/GB10/50889 claims priority to GB 0912051.0, filed Jul. 11, 2009 and GB 0908990.5, filed May 27, 2009. These applications are incorporated by reference herein in their entireties.

FIELD OF DISCLOSURE

The present application relates to optical sensors and, in particular, distributed optical fibre sensors and applications thereof.

BACKGROUND OF DISCLOSURE

The benefits of optical fibres have been demonstrated in a number of sensing applications. The two major areas are: (i) distributed optical fibre sensors, and (ii) multiplexed point sensor arrays.

Distributed sensors utilise the intensity of backscatter light, with Raman and/or Brillouin peaks in the light signal utilised to measure temperature, strain or pressure. Distributed sensors offer a number of advantages including continuous sensing along the entire length of fibre, and flexibility and simplicity of the sensor, which may be standard telecoms optical fibre. For example, a distributed sensor may provide 10,000 measurement points along 10 km of optical fibre with a 1 m spatial resolution. Distributed sensor systems therefore offer low installation and ownership costs.

However, due to their slow response, distributed sensors are usually only used in applications where measurements taking in order of several seconds to hours are acceptable. The most common sensors of this type are the distributed temperature sensors (DTS), which are made by a number of companies. A typical performance of a DTS is 1 m spatial resolution and 1° C. temperature resolution in 60 seconds over a 10 km range.

Distributed sensors have also been used to measure strain by utilising Brillouin shifts in reflected or backscattered light, as described in U.S. Pat. No. 6,555,807 [1] or WO 98/27406 [2]. The frequency of the Brillouin shift is about 1 MHz/10με and its linewidth is about 30 MHz. The strain in an order of 10με can be determined along an optical fibre using the narrow frequency scanning methods described. However, using these approaches, the scanning rate is much slower than the pulse repetition rate and measurement times are typically in the order of few seconds to few minutes.

More recently, a technique for faster measurement of Brillouin frequency shift has been proposed in U.S. Pat. No. 7,355,163 [3]. This technique uses a frequency to amplitude convertor which may be in a form of an optical fibre Mach-Zehnder interferometer with a 3×3 coupler at its output. However, the strain resolution is limited by the linewidth of the Brillouin light and therefore the optical path length difference in the interferometer should be kept within the coherence length of the Brillouin light. Also, the polarisation fading between the two paths of the interferometer, the offset and gain variations of the photodetector receivers would significantly limit the strain measurement. Measurement times of around 0.1 seconds (10 Hz) with strain resolution of 50με have been recently reported using this technique.

For many applications, such as acoustic sensing, much higher sensitivities and faster a measurement time in the order of 1 millisecond (1 kHz), 0.1 millisecond (10 kHz) or 0.01 millisecond (100 kHz) is required.

Multiplexed point sensors offer fast measurements with high sensitivity and are used, for example, in hydrophone arrays. The main application for these in the energy market is for towed and seafloor seismic arrays. However, unlike with distributed sensors, multiplexed point sensors cannot be used where full coverage is required. The size and the position of the sensing elements are fixed and the number of sensors multiplexed on a single fibre is typically limited to 50 to 100 elements. Furthermore, the sensor design relies on additional optical fibre components leading to bulky and expensive array architectures. There is also considerable effort to increase the number of sensors that can be efficiently multiplexed on a single length of fibre.

Optical-time-domain reflectometry (OTDR) is a well known technique that has been used to test optical fibre communications cables. In order to reduce the effect of coherent backscatter interference, which is sometime is referred to as Coherent Rayleigh Noise, a broadband light source is normally used. However, proposals have also been made in U.S. Pat. No. 5,194,847 [4] to use coherent OTDR for sensing intrusion by detecting the fast changes in a coherent backscatter Rayleigh signal. In addition, Shatalin et al. [5] describes using coherent Rayleigh as a distributed optical fibre alarm sensor.

WO 2008/056143 [6] describes a disturbance sensor similar to that of U.S. Pat. No. 5,194,847 [4] using a semiconductor distributed feedback laser source. A fibre Bragg grating filter of preferably 7.5 GHz is used to reject out-of-band chirped light and, thereby, improve the coherence of the laser pulse sent into the fibre. However, this requires matching of the laser wavelength with the narrow band optical filter, which results in the signal visibility variation being reduced compared to a system which uses a very high coherent source as proposed by U.S. Pat. No. 5,194,847.

Similar techniques have also been proposed for the detection of buried optical fibre telecommunication cables (for example in WO 2004/102840 [7]), in perimeter security (GB 2445364 [8] and US2009/0114386 [9]) and downhole vibration monitoring (WO 2009/056855 [10]). However, the response of these coherent Rayleigh backscatter systems has been limited by a number of parameters such as polarisation and signal fading phenomena; the random variation of the backscatter light; and non-linear coherent Rayleigh response. Therefore these techniques are mainly used for event detection and do not provide quantitative measurements, such as the measurement of acoustic amplitude, frequency and phase over a wide range of frequency and dynamic range.

SUMMARY OF DISCLOSURE

The present disclosure provides novel apparatus and methods for fast quantitative measurement of perturbation of optical fields transmitted, reflected and or scattered along a length of an optical fibre.

The present disclosure can be used for distributed sensors, point sensors, or the combination of both.

In particular this technique can be applied to distributed sensors while extending dramatically the speed and sensitivity to allow the detection of acoustic perturbations anywhere along a length of an optical fibre while achieving fine spatial resolution. The present disclosure offers unique advantages in a broad range of acoustic sensing and imaging applications. Typical uses are for monitoring oil and gas wells, for applications such as for distributed flow metering and/or imaging; seismic imaging, monitoring long cables and pipelines; acoustic imaging inside large vessels as well as security applications.

The present disclosure may provide apparatus for highly sensitive and fast quantitative measurement of the phase, frequency and amplitude of the light transmitted, reflected or scattered along a length of an optical fibre.

In the prior art, optical couplers have been used in Michelson or Mach-Zehnder interferometer configurations where the polarisation between the two arms of the interferometer has to be carefully controlled. The novel interferometer in the present disclosure allows an m×m coupler to be utilised using non-reciprocal devices, such as Faraday rotator mirrors and an optical circulator, to provide compensated light interference with a given phase shift that can be measured at all ports of the optical coupler and analysed very quickly, such as at several tens of kilohertz.

Embodiments of the disclosure may be used for multiplexed acoustic point sensors, distributed sensors or a combination of both. In the case of distributed sensors, light pulses are injected into the fibre and the phase modulation of the backscattered light is measured along the fibre at several tens of kilohertz. The fibre can be standard telecommunication fibre and/or cable. Using the techniques described herein, the sensing system can thereby detect the acoustic field along the fibre to provide a distributed acoustic sensor whereby the lengths of the sensing elements can be selected by a combination of adjusting the modulation of the light pulse, the path length in the interferometer as well as the sensing fibre configuration.

The data collected along the fibre are automatically synchronised and they may be combined to provide coherent field images.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the disclosure and how to put it into practice are described by way of example with reference to the accompanying drawings in which:—

FIGS. 1, 2, 3, and 4 show schematically novel interferometer apparatus according to related embodiments of the present disclosure, comprising circulators and multiple fibre couplers with different optical paths through the interferometers, Faraday-rotator mirrors and photodetectors;

FIGS. 5 and 6 show schematically how the interferometers can be cascaded according to embodiments of the disclosure in series and/or star configurations;

FIG. 7 shows schematically a sensor system that utilises the interferometer of an embodiment of the disclosure for fast measurement of scattered and reflected light from an optical fibre;

FIG. 8 shows schematically a distributed sensor system that utilises the interferometer of an embodiment of the disclosure to generate a series of pulses each of different frequency and thereby allowing a different portion of the scattered light to interfere with another portion of the scattered light with a slight frequency shift resulting in a heterodyne beat signal;

FIG. 9 is a block diagram representing a data processing method according to an embodiment of the disclosure;

FIG. 10 is a block diagram representing a method of calibrating the interferometer according to an embodiments of the disclosure;

FIG. 11 shows schematically a distributed sensor system the spectrum of the light that is modulated using a fast optical modulator, that generators multiple frequency side bands with part of spectrum being selected using an optical filter.

FIG. 12A shows the spectrum of the light modulated and selected using the optical filter for the arrangement shown in FIG. 11;

FIG. 12B shows schematically a tinning diagram for a method in accordance with FIG. 11;

FIG. 13 shows schematically an embodiment in which the fibre can be deployed as linear sensors, directional sensors or in a multidimensional array of sensors;

FIGS. 14 to 16 show schematically alternative arrangements of an optical fibre for use in embodiments of the disclosure;

FIGS. 17 to 18 schematically show applications of the disclosure in various aspects.

DETAILED DESCRIPTION

FIG. 1 shows a first embodiment, generally depicted at 100, of a novel interferometer for measuring the optical amplitude, phase and frequency of an optical signal. The incoming light from a light source (not shown) is preferably amplified in an optical amplifier 101, and transmitted to the optical filter 102. The filter 102 filters the out of band Amplified Spontaneous Emission noise (ASE) of the amplifier 101. The light then enters into an optical circulator 103 which is connected to a 3×3 optical coupler 104. A portion of the light is directed to the photodetector 112 to monitor the light intensity of the input light. The other portions of light are directed along first and second optical paths 105 and 106, with a path length difference between the two paths. Faraday-rotator mirrors (FRMs) 107 and 108 reflect the light back through the first and second paths 105 and 106, respectively. The Faraday rotator mirrors provide self-polarisation compensation along optical paths 105 and 106 such that the two portions of light efficiently interfere at each of the 3×3 coupler 104 ports. The optical coupler 104 introduces relative phase shifts of 0 degrees, +120 degrees and −120 degrees to the interference signal, such that first, second and third interference signal components are produced, each at a different relative phase.

First and second interference signal components are directed by the optical coupler 104 to photodetectors 113 and 114, which measure the intensity of the respective interference signal components.

The circulator 103 provides an efficient path for the input light and the returning (third) interference signal component through the same port of the coupler 104. The interference signal component incident on the optical circulator 103 is directed towards photodetector 115 to measure the intensity of the interference signal component.

The outputs of the photodetectors 113, 114 and 115 are combined to measure the relative phase of the incoming light, as described in more detail below with reference to FIGS. 7 and 9.

Optionally, frequency shifters 110 and 111 and/or optical modulator 109 may be used along the paths 105 and 106 for heterodyne signal processing. In addition, the frequency shift of 110 and 111 may be alternated from f1, f2 to f2, f1 respectively to reduce any frequency-dependent effect between the two portions of the light propagating through optical paths 105 and 106.

The above-described embodiment provides a novel apparatus suitable for fast quantitative measurement of perturbation of optical fields, and in particular can be used for distributed and multiplexed sensors with high sensitivity and fast response times to meet requirements of applications such as acoustic sensing.

FIG. 7 shows an application of the interferometer of FIG. 1 to the distributed sensing of an optical signal from an optical system 700. It will be apparent that although the application is described in the context of distributed sensing, it could also be used for point sensing, for example by receiving reflected light from one or more point sensors coupled to the optical fibre.

In this embodiment 700, light emitted by a laser 701 is modulated by a pulse signal 702. An optical amplifier 705 is used to boost the pulsed laser light, and this is followed by a band-pass filter 706 to filter out the ASE noise of the amplifier. The optical signal is then sent to an optical circulator 707. An additional optical filter 708 may be used at one port of the circulator 707. The light is sent to sensing fibre 712, which is for example a single mode fibre or a multimode fibre deployed in an environment in which acoustic perturbations are desired to be monitored. A length of the fibre may be isolated and used as a reference section 710, for example in a “quiet” location. The reference section 710 may be formed between reflectors or a combination of beam splitters and reflectors 709 and 711.

The reflected and the backscattered light generated along the sensing fibre 712 is directed through the circulator 707 and into the interferometer 713. The detailed operation of the interferometer 713 is described earlier with reference to FIG. 1. In this case, the light is converted to electrical signals using fast low-noise photodetectors 112, 113, 114 and 115. The electrical signals are digitised and then the relative optical phase modulation along the reference fibre 710 and the sensing fibre 712 is computed using a fast processor unit 714 (as will be described below). The processor unit is time synchronised with the pulse signal 702. The path length difference between path 105 and path 106 defines the spatial resolution. The photodetector outputs may be digitised for multiple samples over a given spatial resolution. The multiple samples are combined to improve the signal visibility and sensitivity by a weighted averaging algorithm combining the photodetector outputs.

It may be desirable to change the optical frequency of the light slightly to improve the sensitivity of the backscattered or reflected signals. The optical modulator 703 may be driven by a microwave frequency of around 10-40 GHz to generate optical carrier modulation sidebands. The optical filter 708 can be used to select the modulation sidebands which are shifted relative to the carrier. By changing the modulation frequency it is possible to rapidly modulate the selected optical frequency.

Data Processing

FIG. 9 schematically represents a method 1100 by which the optical phase angle is determined from the outputs of the photodetectors 113, 114, 115. The path length difference between path 105 and path 106 defines the spatial resolution of the system. The photodetector outputs may be digitised for multiple samples over a given spatial resolution, i.e. the intensity values are oversampled. The multiple samples are combined to improve the signal visibility and sensitivity by a weighted averaging algorithm combining the photo-detector outputs.

The three intensity measurements I₁, I₂, I₃, from the photodetectors 113, 114, 115 are combined at step 1102 to calculate the relative phase and amplitude of the reflected or backscattered light from the sensing fibre. The relative phase is calculated (step 1104) at each sampling point, and the method employs oversampling such that more data points are available than are needed for the required spatial resolution of the system.

Methods for calculating the relative phase and amplitude from three phase shifted components of an interference signal are known from the literature. For example, Zhiqiang Zhao et al. [12] and U.S. Pat. No. 5,946,429 [13] describe techniques for demodulating the outputs of 3×3 couplers in continuous wave multiplexing applications. The described techniques can be applied to the time series data of the present embodiment.

For each sampling point, a visibility factor V is calculated at step 1106 from the three intensity measurements I₁, I₂, I₃, from the photodetectors 113, 114, 115, according to equation (1), for each pulse.

V=(I ₁ −I ₂)²+(I ₂ −I ₃)²+(I ₃ −I ₁)²  Equation (1)

At a point of low visibility, the intensity values at respective phase shifts are similar, and therefore the value of V is low. Characterising the sampling point according the V allows a weighted average of the phase angle to be determined (step 1108), weighted towards the sampling points with good visibility. This methodology improves the quality of the phase angle data 1110.

Optionally, the visibility factor V may also be used to adjust (step 1112) the timing of the digital sampling of the light for the maximum signal sensitivity positions. Such embodiments include a digitiser with dynamically varying clock cycles, (which may be referred to herein as “iclock”). The dynamically varying clock may be used to adjust the timing of the digitised samples at the photodetector outputs for the position of maximum signal sensitivity and or shifted away from positions where light signal fading occurs.

The phase angle data is sensitive to acoustic perturbations experienced by the sensing fibre. As the acoustic wave passes through the optical fibre, it causes the glass structure to contract and expand. This varies the optical path length between the backscattered light reflected from two locations in the fibre (i.e. the light propagating down the two paths in the interferometer), which is measured in the interferometer as a relative phase change. In this way, the optical phase angle data can be processed at 1114 to measure the acoustic signal at the point at which the light is generated.

In one or more embodiments of the present disclosure, the data processing method 1100 is performed utilising a dedicated processor such as a Field Programmable Gate Array.

Sensor Calibration

For accurate phase measurement, it is important to measure the offset signals and the relative gains of the photo-detectors 113,114 and 115. These can be measured and corrected for by method 1200, described with reference to FIG. 10.

Each photodetector has electrical offset of the photodetectors, i.e. the voltage output of the photodetector when no light is incident on the photodetector (which may be referred to as a “zero-light level” offset. As a first step (at 1202) switching off the incoming light from the optical fibre and the optical amplifier 101. When switched off, the optical amplifier 101 acts as an efficient attenuator, allowing no significant light to reach the photodetectors. The outputs of the photodetectors are measured (step 1204) in this condition to determine the electrical offset, which forms a base level for the calibration.

The relative gains of the photodetectors can be measured, at step 1208, after switching on the optical amplifier 101 while the input light is switched off (step 1206). The in-band spontaneous emission (i.e. the Amplified Spontaneous Emission which falls within the band of the bandpass filter 102), which behaves as an incoherent light source, can then be used to determine normalisation and offset corrections (step 1210) to calibrate the combination of the coupling efficiency between the interferometer arms and the trans-impedance gains of the photodetectors 113, 114 and 115. This signal can also be used to measure the signal offset, which is caused by the in-band spontaneous emission.

Conveniently, the optical amplifier, which is a component of the interferometer, is used as in incoherent light source without a requirement for an auxiliary source. The incoherence of the source is necessary to avoid interference effects at the photodetectors, i.e. the coherence length of the light should be shorter than the optical path length of the interferometer. However, for accurate calibration it is preferable for the frequency band of the source to be close to, or centred around, the frequency of light from the light source. The bandpass filter 102 is therefore selected to filter out light with frequencies outside of the desired bandwidth from the Amplified Spontaneous Emission.

When used in a pulsed system, such as may be used in a distributed sensor, the above-described method can be used between optical pulses from the light source, to effectively calibrate the system during use, before each (or selected) pulses from the light source with substantively no interruption to the measurement process.

Variations to the above-described embodiments are within the scope of the disclosure, and some alternative embodiments are described below. FIG. 2 shows another embodiment, generally depicted at 200, of a novel interferometer similar to that shown in FIG. 1 but with an additional Faraday-rotator mirror 201 instead of photodetector 112. Like components are indicated by like reference numerals. In this case the interference between different paths, which may have different path length, can be separated at the three beat frequencies f₁, f₂ and (f₂−f₁). The arrangement of this embodiment has the advantage of providing additional flexibility in operation, for example the different heterodyne frequencies can provide different modes of operation to generate measurements at different spatial resolutions.

FIG. 3 shows another embodiment of a novel interferometer, generally depicted at 300, similar to the arrangement of FIG. 1, with like components indicated by like reference numerals. However, this embodiment uses a 4×4 coupler 314 and an additional optical path 301, frequency shifter 304, phase modulator 303, Faraday-rotator mirror 302 and additional photo-detector 308. In this case the interference between different paths, which may have different path length differences, can be separated at the three beat frequencies (f₂−f₁), (f₃−f₂) and (f₃−f₁). Alternatively, the Faraday-rotator mirror 302 may be replaced by an isolator or a fibre matched end so that no light is reflected through path 301, so only allowing interference between path 105 and 106.

The 4×4 optical coupler of this arrangement generates four interference signal components at relative phase shifts of −90 degrees, 0 degrees, 90 degrees, 180 degrees.

FIG. 4 shows another embodiment of the interferometer. In this case an additional path is introduced in the interferometer by inserting a Faraday-rotator mirror 402 instead of the photo-detector 112.

In all of the above-described embodiments, optical switches may be used to change and/or select different combinations of optical path lengths through the interferometer. This facilitates switching between different spatial resolution measurements (corresponding to the selected path length differences in the optical path lengths).

FIGS. 5 and 6 show examples of interferometer systems 500, 600 arranged for used in cascaded or star configurations to allow the measuring of the relative optical phase for different path length differences. In FIG. 5, three interferometers 501, 502, 503 having different path length differences (and therefore different spatial resolutions) are combined in series. In FIG. 6, four interferometers 602, 603, 604 and 605 having different path length differences (and therefore different spatial resolutions) are combined with interferometers 602, 603, 604 in parallel, and interferometers 603 and 605 in series. In FIG. 6, 601 is a 3×3 coupler, used to split the light between the interferometers. Arrangement 600 can also be combined with wavelength division multiplexing components to provide parallel outputs for different optical wavelengths.

The embodiments described above relate to apparatus and methods for fast quantitative measurement of acoustic perturbations of optical fields transmitted, reflected and or scattered along a length of an optical fibre. The disclosure in its various aspects can be applied or implemented in other ways, for example to monitor an optical signal generated by a laser, and/or to monitor the performance of a heterodyne signal generator, and to generate optical pulses for transmission into an optical signal. An example is described with reference to FIG. 8.

FIG. 8 shows a system, generally depicted at 800, comprising an interferometer 801 in accordance with an embodiment of the disclosure, used to generate two optical pulses with one frequency-shifted relative to the other. The interferometer receives an input pulse from a laser 701, via optical circulator 103. A 3×3 optical coupler 104 directs a component of the input pulse to a photodetector, and components to the arms of the interferometer. One of the arms includes a frequency shifter 110 and an RF signal 805. The interference between the two pulses is monitored by a demodulator 802. The light reflected by Faraday-rotator mirrors 107 and 108 is combined at the coupler 809 using a delay 803 to match the path length of the interferometer, so that the frequency shifted pulse and the input pulse are superimposed. The coupler 809 introduces relative phase shifts to the interference signal, and interferometer therefore monitors three heterodyne frequency signal components at relative phase shifts. The optical circulator 103 passes the two pulses into the sensing fibre.

In this embodiment, the reflected and backscattered light is not detected by an interferometer according to the present disclosure. Rather, the reflected and backscattered light is passed through an optical amplifier 804 and an optical filter 806 and are then sent to a fast, low-noise photodetector 807. The electrical signal is split and then down-converted to baseband signals by mixing the RF signal 805 at different phase angles, in a manner known in the art. The electrical signals are digitised and the relative optical phase modulation at each section of the fibre is computed by combining the digitised signals using a fast processor 808.

FIG. 11 shows another embodiment of apparatus for point as well as distributed sensors. In this case the modulation frequency 704 of the optical modulator 703 is switched from f1 to f2 within the optical pulse modulation envelope.

The optical filter 708 selects two modulation frequency sidebands 1202/1203 and 1204/1205 generated by the optical modulator as indicated in FIG. 12. The frequency shift between first order sidebands 1202 and 1203 is proportional to the frequency modulation difference (f2−f1) whereas the frequency shift between 2^(nd) order sidebands 1204 and 1205 is proportional to 2(f2−f1). Therefore, the photo-detector output 806 generates two beat signals, one of which is centred at (f2−f1) and the other at 2(f2−f1). Using the demodulator 901, the relative optical phase of the beat signals can be measured independently. The two independent measurements can be combined to improve the signal visibility, the sensitivity and the dynamic range along the sensing fibre.

FIG. 12A shows the modulation spectrum of the light and the selection of the sidebands referred to above.

FIG. 12B shows the original laser pulse 1206 with pulse width of T at frequency f₀ which is modulated at frequency f1, f2 and f3 during a period T1, T2 and T3, respectively. The delay between T1, T2 and T3 can also be varied. One or more modulation sidebands is/are selected with the optical filter 708 to generated a frequency shifted optical pulses that are sent into the fibre. The reflected and/or backscatter signals (709, 710, 711 and 712) from the fibre from is directed to a photodetector receive via a circulator 707. The reflected and or backscatter light from different pulses mix together at the photodetector output to generate heterodyne signals such (f2−f1), (f3−f1), (f3−f2), 2(f2−f1), 2(f3−f1) and 2(f3−f2). Other heterodyne signals are also generated but (2f2−f1), (2f3−f1), (2f1−f2), (2f1−f3), (2f3−f1) and (2f3−f2) are also generated at much higher frequencies. The heterodyne signal are converted down to base band in-phase and quadrature signals. The in-phase and quadrature signals are digitise by a fast analogue to digital convertors and the phase angle is computed using fast digital signal processor.

FIG. 13 shows an embodiment with distributed sensors with the sensing fibre 702 subjected to different perturbation fields 1302, 1304 and 1307. The sensing fibre can be used as linear sensors 1303 and 1304, as directional sensors 1305 and 1306 or as multidimensional array sensors 1308, 1309 and 1310. Since all the measurements are synchronised, they can be processed to enhance the signal sensitivity, achieve a wide dynamic range and provide field imaging using beam forming techniques.

FIG. 14 shows an optical fibre arrangement 1400, where the fibre is placed on a surface area in a continuous path without crossing over another part of the fibre to increase the sensitivity, in a double figure-eight pattern.

FIG. 15 shows an optical fibre arrangement 1500, where the fibre is placed on a surface area in a continuous path without crossing over another part of the fibre to increase the sensitivity, in a folded three-Omegas (Ω Ω Ω) pattern.

These arrangements are particularly useful to increase the sensing sensitivity, frequency response and the spatial resolution of the sensing system, while simplifying installation techniques and minimising bending losses.

FIG. 16 shows an optical fibre arrangement 1600, where the fibre is placed in a logarithmic spiral pattern to form an acoustic camera or telescope. Acoustic energy can be detected all along a section of fibre. In this case the signals detected along the field are synchronised and using addition signal processing such as beam forming, the near-field and far-field acoustic emission can be mapped. Such an apparatus can be used to look far into the sky, through oceans, deep into the ground, or within vessels. This aspect also provides apparatus for monitoring the environmental noise such as aircraft noise during take-off and landing as well as noise from other flying objects or natural habitats.

FIG. 17 shows at 1700 an application to distributed flow sensing along a pipe 1702 at different sections with fibre 1701 wrapped around the pipe at separated locations 1704 and attached or placed close to the pipe via clamps 1706 to measure the flow noise and pressure variations. This arrangement may also be used to monitor the operation of injector or control valves 1708, and sensors may be used for in-well perforated zones monitoring and sand production monitoring. For example, for in-well applications, the acoustic noise profile can be used to measure the flow by noise logging at every location along the well. In addition, the noise spectrum can be used to identify the phase of the fluid. Further noise spectrum correlation techniques can be used over a long section of the well to determine the speed of sound as well as tracking eddies generated within the flow to accurately determine the flow rates, using analysis techniques for example as described in WO 2006/130499 [14]. This document describes an array of optical fibre acoustic interferometric sensors used to track the speed of the vortices induced pressure waves as a function of the flow. However, the interferometers require discrete components, such as Bragg grating pairs, and a limited number of sensors over a short section of a pipe can be practically be used. With the distributed acoustic sensor of the present disclosure we can use a flexible method of attaching to or placing close to a pipe a continuous length of optical in an optimised configuration along entire length of pipe. For example the spatial resolution measurements may be increased by wrapping the fibre around the pipe to track the vortices induced pressure waves or simply track the acoustic waves generated and propagated along the pipe to determine the speed of sound both in the same and opposite directions of the flow. The speed of sound is a function of the fluid composition and by mapping the speed of sound one can visualise how the flow profile changes along the pipe.

Also, since we do not require any discrete components, a higher operating temperature can be achieved with proper coating protection applied on to the fibre. The fibre sensitivity can also be enhanced or reduced using different coatings or jackets. Also, the fibre can be made into a continuous cable with an enhanced sensing sensitivity while proving a protection for the fibre in harsh environments.

FIG. 18 shows at 1800 an application to dynamic positioning of a riser 1802 using acoustic fibre optic sensors 1804 and acoustic reference sources 1806 whereby the optical fibre sensor 1804 measures the time of flight of acoustic signals received at different locations along the riser and thereby determines the position of the riser.

Review of Features of the Disclosure in Various Aspects and Embodiments

In one aspect, the present disclosure provides an optical interferometer apparatus which can provide multiple path differences between the optical signals and provide interference signals between different optical paths with fixed and/or variable phase shifts. The interferometer utilises beam splitting components, circulating devices and Faraday rotator mirrors in a novel configuration. The optical signals at the output of the interferometer are converted to electrical signals which digitised for fast processing. The offset levels of the electrical signals are removed and their amplitude are normalised. The relative phase shifts of optical signals are accurately determined by combining the normalised electrical signals.

In another aspect, the present disclosure relates to an interferometer apparatus that utilises beam splitters and non-reciprocal devices to provide light interference with given phase shifts and path length differences that can be measured at all ports of the beam splitters whereby the relative phase modulation of the light can be computed very accurately and quickly, such as at every few nanoseconds. The interferometer may use optical fibre components such as an m×m fused optical fibre coupler that is connected to an optical fibre circulator at one of its ports; Faraday-rotator mirrors that reflect and, at the same time, provide polarisation compensation for the light propagating through the different paths of the interferometer and photodetectors that are used to measure the interference light signals. The incoming optical light may be amplified using an optical fibre amplifier, and preferably the interferometer has a pass band optical filter to filter out the out of band Amplified Spontaneous Emission noise (ASE). The interferometer may provide birefringence compensation for light propagating along different optical paths through the interferometer. This provides sufficiently high visibility at the outputs of the interferometer.

In another of its aspects, the present disclosure provides a method for compensating the offset and the gain of the photo-detectors, and the coupling ratio of the interferometer arms, to normalise the resultant interference signals used to measure the relative phase of the modulated input light in any of preceding claims where the detector offset is measured by switching off the optical amplifier in the backscatter path; the resultant photo-detector offset and gain then being determined by switching on the amplifier while the input light is switched off; the ASE of the optical amplifier then acts as an independent incoherent light source and thereby the offsets and relative gains of the photo-detectors can be determined and the detected light signals normalised. The method may therefore use incoherent light that enters the input of the interferometer to normalise the relative signal amplitudes at the output of the photo-detectors. For example, when an optical preamplifier is used at the input of the interferometer, the spontaneous light emission can be used to measure the combination of the splitting ratio of the interferometer arms and the relative gains of the photo-detectors and thereby normalise the relative signal amplitudes accordingly.

Another additional feature of the present disclosure is to use phase modulators and/or frequency shifters to shift the relative frequency and or vary the phase between the optical paths of the interferometer. Frequency shifters and/or phase modulators may be used to provide heterodyne signals and/or to separate the resultant interference light signal from different paths through the interferometer.

An additional feature of an embodiment of the disclosure is selecting the frequency of the frequency shifter sufficiently high so that at least one cycle of the beat frequency results within one light pulse resolution. Different frequency shifts may be used between different optical paths of the interferometer for the separation and/or heterodyne detection of the phase between different optical paths. The frequency shifts between different optical paths may be alternated to correct for any frequency dependency of the interferometer output signals.

An additional feature of an embodiment of the disclosure is the selection of different optical paths through the interferometer such as by using optical switches. The optical switches may be used to select different optical paths through the interferometer and thereby select a different spatial resolution measurement. Another aspect of the present disclosure relates to a system comprising a number of interferometers cascaded in a series or in a star configuration or a combination of both.

The disclosure also provides a system that utilises a light pulse for multiplexed and/or distributed sensors by measuring the phase modulation of the reflected and/or the backscattered light along a length of fibre with high sensitivity, high dynamic range and a high speed of over tens of kilohertz. In this way, the present disclosure can provide a multiplexed and/or distributed acoustic sensing system.

An additional feature of an embodiment of the disclosure is digitising the outputs of the interferometer, or the photodetectors of the interferometer, at least twice over a spatial resolution interval. An additional feature of an embodiment of the disclosure is combining the outputs of the interferometer to determine the insensitive measurement sample points resulting from any signal fading of the light in order to reject and/or provide a weighted signal average of the multiple samples of the light over a given spatial resolution measurement or interval. Embodiments of the disclosure use a digitiser with dynamically varying clock cycles, (which may be referred to herein as “iclock”), to adjust the timing of the digital sampling of the light for the maximum signal sensitivity positions. The dynamically varying clock may be used to adjust the timing of the digitised samples at the photo-detector outputs for the position of maximum signal sensitivity and or shifted away where light signal fading occurs.

A further aspect of one or more embodiments of the disclosure provides frequency shifted light, using a fast optical modulator to generate sidebands, preferably with a suppressed carrier spectrum, and a band-pass optical filter to select the modulation sidebands whereby the modulation frequency is varied rapidly between two portions of light pulse propagating through the optical modulator. The optical modulator may also chop off a portion of light pulse in the middle so as to generate two pulses with different frequencies. In this case the reflected and/or the backscattered light generated by the two pulses are combined to result in a heterodyne signal whose phase is determined to measure the relative optical phase modulation along the sensing fibre.

Providing multiple heterodyne signals can improve the dynamic range and reduce the effect of signal fading. When the scattered and/or the reflected light from the two pulses are combined, the modulation sidebands generate different beat frequencies which are proportional to the modulation frequency difference and to the order of the sidebands. The frequency of the light may be changed to optimise the signal sensitivity over a given section of the fibre. The frequency of the light passing through the optical modulator may be changed rapidly so that at least two portions of light pulse have different modulation sideband frequencies and, in addition, part of the light pulse may be chopped to generate two distinct portions of light pulses with different modulation sideband frequencies. The modulation sidebands between the two portions of the light pulse scattered or reflected from a sensing fibre may beat together to generate multiple heterodyne signals at multiples of the frequency difference between the two pulses that are proportional to the order of the modulation sidebands.

Embodiments of the disclosure may use a laser light or a broadband light source. Coherent matching of the light with the same delay results in an interference signal that can be used to measure the relative phase modulation of the scattered or reflected light along the fibre. Embodiments disclosed herein may use wavelength division multiplexed components to utilise multiple laser light pulses with different wavelengths and, preferably, varying time shift with respect to each to control the cross-phase modulation between the light pulses and to allow the processing of multiple pulses in the sensing fibre without and cross-sensitivity to allow the system to achieve a higher measurand frequency response. This may be the acoustic frequency response of the system to provide a different spatial sampling resolutions and/or positions, and/or to allow the efficient rejection of any points with low sensitivity.

An additional feature of one or more embodiments of the disclosure is the selection of different spatial resolutions whereby the sensitivity and the frequency response along the sensing fibre can be adjusted, and the dynamic range can be widened.

The sensing fibre may be standard single mode fibre, polarisation maintaining fibre, a single polarisation fibre, and or a ribbon fibre, and it can be coated and or cabled to enhance or to suppress its sensitivity.

An additional feature of one or more embodiments of the disclosure is the selection of different configurations of the fibre to optimise the sensitivity, the frequency and the directionality of the sensing fibre at different locations. The fibre may be deployed as linear sensors, direction sensors or multidimensional array sensors. The fibre may be placed on a surface area in a continuous path without crossing over another part of the fibre to increase the sensitivity, the frequency response and or the spatial resolution of the sensor system such as in a folded three-Omegas (Ω Ω Ω) and or double eights (88) configurations. This is particularly useful to increase the sensing sensitivity, frequency response and the spatial resolution of the sensing system, while simplifying installation techniques and minimising bending losses.

The fibre may be attached on a surface of a vessel to listen to the noise generated within the vessel to monitor the changes in the process, acoustically image the process, as well to detect any leaks.

A further aspect provides an apparatus using acoustic sensors for distributed flow measurement and imaging, in-well perforated zones monitoring and sand production monitoring. For example, for in-well applications, the acoustic noise profile can be used to measure the flow by noise logging at every location along the well. In addition, the noise spectrum can be used to identify the phase of the fluid. Further noise spectrum correlation techniques can be used over a long section of the well to determine the speed of sound as well as tracking eddies generated within the flow to accurately determine the flow rates.

The sensor systems may be used as a distributed acoustic sensor, enabling the determination of distributed flow measurement and imaging, perforated zones monitoring and sand production monitoring in oil and gas wells and flowlines. The distributed temperature and strain measurements may be combined to enhance the data interpretation of the distributed acoustic sensor.

A further application is listening along previously installed optical fibres for surveillance applications. This includes measurements along fibres installed along boreholes, pipelines, perimeters, ports and borders.

An additional aspect provides a dynamic positioning apparatus using acoustic fibre optic sensors and acoustic reference sources whereby the optical fibre sensor measures the time of flight of acoustic signals received at different locations along the structure and thereby determines its position.

A further aspect provides pipeline structure monitoring apparatus using an acoustic fibre sensor and a pig that emits a sound (known as a “whistling pig”). The optical fibre sensor measures the acoustic transmission through the wall of the pipe for diagnostics as well as for tracking the position of the pig.

Another aspect provides pipeline monitoring apparatus where the sensing fibre is deployed inside the pipeline and carried along the pipeline by the fluid drag to provide a measurement of the noise flow for diagnostics of the pipeline as well as for flow characterisation and/or imaging.

Another aspect provides an apparatus using a fibre sensor used for acoustic sensing and an energy harvesting self-powered acoustic source to generate sufficient acoustic emission that can be picked up by a nearby sensing fibre for data communication, measurement, diagnostics and surveillance applications including along long pipelines, in-well and in other remote applications.

Another aspect of the present disclosure provides an apparatus using acoustic fibre sensors to measure seepage rates along dams and dykes by generating an acoustic noise source in the upstream reservoir or in the core of the dam and measuring the acoustic signal strength detected along the fibre whereby areas of seepage act as low acoustic impedance paths for acoustic wave transmission and thereby exhibiting louder signal levels.

Other advantages and applications of the present disclosure will be apparent to those skilled in the art. Any of the additional or optional features can be combined together and combined with any of the aspects, as would be apparent to those skilled in the art.

CONCLUDING REMARKS

As has been described above, apparatus and methods for fast quantitative measurement of perturbations of optical fields transmitted, reflected and/or scattered along a length of an optical fibre. In particular, the present disclosure can be used for distributed sensing while extending dramatically the speed and sensitivity to allow the detection of acoustic perturbations anywhere along a length of an optical fibre while achieving fine spatial resolution. The present disclosure offers unique advantages in a broad range of acoustic sensing and imaging applications. Typical uses are for monitoring oil and gas wells such as for distributed flow metering and/or imaging, monitoring long cables and pipelines, imaging of large vessels as well as security applications.

There follows a set of numbered features describing particular embodiments of the invention. Where a feature refers to another numbered feature then those features may be considered in combination.

1. An optical sensor system comprising: a light source generating a pulsed optical signal; an optical sensing fibre configured to receive the optical signal; an optical modulator for generating frequency sidebands in the optical signal; an optical filter configured to controllably select one or more of the modulation sidebands, and, thereby vary the frequency of the light input to the sensing fibre.

2. The system of feature 1, where the frequency of the light is changed to optimise the signal sensitivity over a given section of the fibre.

3. The system of feature 1 or feature 2, where the frequency of the light passing through the optical modulator is changed rapidly so that at least two portions of light pulse have different modulation sideband frequencies.

4. The system of any preceding feature wherein part of the light pulse is chopped to generate two distinct portions of light pulses with different modulation sideband frequencies.

5. The system of feature 4 wherein the modulation sidebands between the two portions of the light pulse scattered or reflected from a sensing fibre beat together to generate multiple heterodyne signals at multiples of the frequency difference between the two pulses that are proportional to the order of the modulation sidebands.

6. The system of any preceding feature wherein the light source is a laser light or a broadband light source.

7. The system of any preceding feature wherein using wavelength division multiplexed components to utilise multiple laser light pulses with different wavelengths and, preferably, varying time shift with respect to each to control the cross-phase modulation between the light pulses and to allow the processing of multiple pulses in the sensing fibre without and cross-sensitivity to allow the system to achieve a higher measurand frequency response, such as higher acoustic frequency response, and to allow the efficient rejection of any points with low sensitivity.

8. The system of any of the above features where the sensing fibre is a single mode fibre, polarisation maintaining fibre, a single polarisation fibre, multimode fibre and or a ribbon fibre.

9. The sensor system of any preceding feature used as a distributed acoustic sensor.

10. The sensor system of feature 9 where the distributed sensor can be connected to standard optical fibre for pipelines, perimeters, ports or border security.

REFERENCES

-   [1] U.S. Pat. No. 6,555,807, Clayton et al. -   [2] WO 98/27406, Farhadiroushan et al. -   [3] U.S. Pat. No. 7,355,163, Watley et al. -   [4] U.S. Pat. No. 5,194,847, Taylor et al. -   [5] Shatalin, Sergey et al., “Interferometric optical time-domain     reflectometry for distributed optical-fiber sensing”, Applied     Optics, Vol. 37, No. 24, pp. 5600-5604, 20 Aug. 1998. -   [6] WO 2008/056143, Shatalin et al. -   [7] WO 2004/102840, Russel et al. -   [8] GB 2445364, Strong et al. -   [9] US 2009/0114386, Hartog et al. -   [10] WO 2009/056855, Hartog et al. -   [11] WO 2007/049004, Hill et al. -   [12] Zhiqiang Zhao et al., “Improved Demodulation Scheme for Fiber     Optic Interferometers Using an Asymmetric 3×3 Coupler”, J. Lightwave     Technology, Vol. 13, No. 11, November 1997, pp. 2059-2068 -   [13] U.S. Pat. No. 5,946,429, Huang et al -   [14] WO 2006/130499, Gysling et al. 

1.-24. (canceled)
 25. A method of monitoring the position of a structure using a distributed acoustic sensor (DAS) system, the method, comprising: providing a structure to be monitored; deploying a plurality of acoustic reference sources in an area in which a structure is located; deploying an optical fiber distributed acoustic sensor system on the structure, the optical fiber distributed acoustic sensor system comprising a sensing optical fiber that extends along the structure; emitting acoustic signals from the plurality of acoustic reference sources; using the optical fiber distributed acoustic sensor system to detect, at a plurality of acoustic sensing points along the sensing optical fiber, the acoustic signals emitted by the plurality of acoustic reference sources; calculating relative positions of a plurality of the acoustic sensing points in dependence on the detected acoustic signals from the acoustic sources; and from the calculated positions of the acoustic sensing points along the fiber, determining a position the structure.
 26. A method according to claim 25, wherein the using the optical fiber distributed acoustic sensor to detect the acoustic signals emitted by the plurality of acoustic reference sources comprises measuring the time of flight of the emitted acoustic signals received at the plurality of acoustic sensing points.
 27. A method according to claim 25, further comprises: inputting a pulsed optical signal to the sensing optical fiber; receiving backscattered and/or reflected light from along the sensing optical fiber as the pulsed optical signal travels there along, the light being backscattered and/or reflected in dependence on the acoustic signals incident along the fiber; and processing the received light to detect the emitted acoustic signals.
 28. A method according to claim 27, wherein the processing further comprises measuring the relative phase, frequency and amplitude of the light received from along the length of the sensing optical fiber.
 29. A method according to claim 28, wherein the relative phase, frequency and amplitude measurements taken along the length of the sensing optical fiber are synchronised.
 30. A method according to claim 27, wherein receiving the backscattered and/or reflected light is performed using an interferometer, the interferometer comprising at least two optical paths with a path length difference therebetween such that the received backscattered and/or reflected light interferes in the interferometer to produce interference components
 31. A method according to claim 25, wherein the structure is a subsea riser.
 32. A system for monitoring the position of a structure using a distributed acoustic sensor (DAS) system, the method, comprising: a structure to be monitored; a plurality of acoustic reference sources arranged to emit acoustic signals; and a distributed acoustic sensor (DAS) system, the distributed acoustic sensor system comprising a sensing optical fiber deployed such that the fiber extends along the structure, the distributed acoustic sensor system being arranged to: detect, at a plurality of acoustic sensing points along the sensing optical fiber, the acoustic signals emitted by the plurality of acoustic reference sources; calculate relative positions of a plurality of the acoustic sensing points in dependence on the detected acoustic signals from the acoustic sources; and from the calculated positions of the acoustic sensing points along the fiber, determine a position the structure.
 33. A system according to claim 32, wherein the distributed acoustic sensor system is arranged to measure the time of flight of the acoustic signals received at the plurality of sensing points.
 34. A system according to claim 32, wherein the distributed acoustic sensor system further comprises: an optical source arranged to input a pulsed optical signal to the sensing optical fiber; means for receiving backscattered and/or reflected light from along the sensing optical fiber as the pulsed optical signal travels there along, the light being backscattered and/or reflected in dependence on the acoustic signals incident along the fiber; and means for processing the received light to detect the emitted acoustic signals.
 35. A system according to claim 34, wherein the means for processing is further arranged to measure the relative phase, frequency and amplitude of the light received from along the length of the sensing optical fiber.
 36. A system according to claim 35, wherein means for processing is further arranged to synchronise the relative phase, frequency and amplitude measurements taken along the length of the sensing optical fiber.
 37. A system according to claim 34, wherein the means for receiving is an interferometer comprising at least two optical paths with a path length difference therebetween such that the received backscattered and/or reflected light interferes in the interferometer to produce interference components.
 38. A system according to claim 32, wherein the structure is a subsea riser. 